Hannu Koivisto scite author profile

In this paper, a multiobjective genetic fuzzy system (GFS) to learn the granularities of fuzzy partitions, tuning the membership functions (MFs), and learning the fuzzy rules is presented. It uses dynamic constraints, which enable three-parameter MF tuning to improve the accuracy while guaranteeing the transparency of fuzzy partitions. The fuzzy models (FMs) are initialized by a method that combines the benefits of Wang-Mendel (WM) and decision-tree algorithms. Thus, the initial FMs have less rules, rule conditions, and input variables than if WM initialization were to be used. Moreover, the fuzzy partitions of initial FMs are always transparent. Our approach is tested against recent multiobjective and monoobjective GFSs on six benchmark problems. It is concluded that the accuracy and interpretability of our FMs are always comparable or better than those in the comparative studies. Furthermore, on some benchmark problems, our approach clearly outperforms some comparative approaches. Suitability of our approach for higher dimensional problems is shown by studying three benchmark problems that have up to 21 input variables.

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Neural networks in process fault diagnosis

Sorsa

Koivo

Koivisto

1991

IEEE Trans. Syst., Man, Cybern.

251

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Fuzzy classifier identification using decision tree and multiobjective evolutionary algorithms

Pulkkinen

Koivisto

2008

International Journal of Approximate Reasoning

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Developing a bioaerosol detector using hybrid genetic fuzzy systems

Pulkkinen

Hytönen

Koivisto

2008

Engineering Applications of Artificial Intelligence

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Optimization of a True Moving Bed unit and determination of its feasible operating region using a novel Sliding Particle Swarm Optimization

Nogueira

Martins

Requião

et al. 2019

Computers & Industrial Engineering

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Circular correlation based identification of switching power converter with uncertainty analysis using fuzzy density approach

Roinila

Helin

Vilkko

et al. 2009

Simulation Modelling Practice and Theory

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Modelling of a pressure swing adsorption unit by deep learning and artificial Intelligence tools

Oliveira

Koivisto

Iwakiri

et al. 2020

Chemical Engineering Science

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A quasi-virtual online analyser based on an artificial neural networks and offline measurements to predict purities of raffinate/extract in simulated moving bed processes

Nogueira

Ribeiro

Requião

et al. 2018

Applied Soft Computing

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Hannu Koivisto

A Dynamically Constrained Multiobjective Genetic Fuzzy System for Regression Problems

Neural networks in process fault diagnosis

Fuzzy classifier identification using decision tree and multiobjective evolutionary algorithms

Developing a bioaerosol detector using hybrid genetic fuzzy systems

Optimization of a True Moving Bed unit and determination of its feasible operating region using a novel Sliding Particle Swarm Optimization

Circular correlation based identification of switching power converter with uncertainty analysis using fuzzy density approach

Modelling of a pressure swing adsorption unit by deep learning and artificial Intelligence tools

A quasi-virtual online analyser based on an artificial neural networks and offline measurements to predict purities of raffinate/extract in simulated moving bed processes

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